Expression of a synthetic gene coding for the amino acid sequence of Clostridium pasteurianum rubredoxin

A synthetic gene based on the published amino acid sequencefor Clostridium pasteurianum rubredoxin was constructed, clonedin Escherichia coli 71/18 and expressed using the T7 RNA polymerase/promotersystem in E.coli HMS273. UV/visible spectroseopy and metal analysesindicated that the as–isolated synthetic gene productis a mixture of holo–(i.e. iron–containing) rubredoxinand zinc–substituted rubredoxin, with the latter amountingto {small tilde} 70% of the total rubredoxin. Hie UV/visibleabsorption and resonance Raman spectra of the cloned holorubredoxinare characteristic of the native rubredoxin–type ironsite. N–terminal amino acid sequencing suggests that thegene product consists of at least three polypeptide specieswith the initial sequences (approximate relative abundances):Met–Met–Lys–... (63%), blocked (30%) and Met–Lys–...(7%). The blocked portion presumably consists of a mixture ofnMet–Met–Lys–... and nMet-Lys–..., wherenMet represents an amino–blocked methionine residue.     

Mutant forms of {beta}-galactosidase with an altered requirement for magnesium ions

By random approaches we have previously isolated many variantsof Escherichia coli ß-galactosidase within a shortcontiguous tract near the N-terminus (residues 8–12 ofwildtype enzyme), some of which have increased stability towardsheat and denaturants. The activity of these mutants was originallyanalysed and quantitated in situ in activity gels without theaddition of magnesium ions to the buffer system. We now showthat the improved stability is only observable under such conditionsof limiting magnesium ion concentrations or in the presenceof appropriate concentrations of a metal chelator. In the presenceof EDTA, purified preparations of one of these mutant enzymeswere much more resistant to denaturants than wild-type, butthis differential was completely nullified in the presence of1 mM Mg²⁺. However, the stability of this mutant enzyme in EDTAwas lower than that shown by it, or the wild-type enzyme, inthe presence of magnesium ions. In addition, certain alterationswithin another N-terminal tract (residues 27–31 of wild-type)resulted in enzymes with greater dependence on Mg²⁺ than naturalß-galactosidase. We conclude that a small number ofresidue changes in a large protein can profoundly modulate therequirement for metal ion stabilization, allowing partial abrogationof this need in certain cases. Thus, some enzymes which requiredivalent metal ions for structural purposes only may be engineeredtowards metal independence.     

Determination of the pKa values of titratable groups of an antigen-antibody complex, HyHEL-5-hen egg lysozyme

The titration behavior of the ionizable residues of the HyHEL-5–henegg lysozyme complex and its individual components has beenstudied using continuum electrostatic calculations. Severalresidues of HyHEL-5 had pK_a values shifted away from model valuesfor isolated residues by more than three pH units. Shifts awayfrom the model values were smaller for the residues of hen egglysozyme. A moderate variation in the pK_a values of the titratablegroups was observed upon increase of the ionic strength from0 to 100 mM, amounting to 1–2 pH units in most cases.Under physiological conditions, the net charge of HyHEL-5 wasopposite that for hen egg lysozyme. Several residues, includingthose involved in the Arg–Glu salt bridges that have beenproposed to be important in antibody-antigen binding, had pK_avalues that were changed significantly upon binding. The maintitration event upon antibody-antigen binding appears to beloss of a proton from residue GluH50 of the Fv molecule. Thelimitations of our calculation methods and the role they mightplay in the design of antibodies for use in assays, sensorsand separations are discussed     

The evolution of sugar isomerases

L-Arabinosc isomerase (EC 5.3.1.4 [EC] ) catalyzes the isomerizationof L-arabinose to L-ribulose. Here we report on the purification,kinetic mechanism and chemical mechanism of L-arabinose isomerasefrom Escherichia coli. The enzyme catalyzes the isomerizationof L-arabinose to L-ribulose by a proton transfer mechanism,in contrast to xylose isomerase which uses a hydride transfermechanism to perform a similar isomerization. Arabinose isomeraseactivity is metal dependent, although the enzyme can catalyzethe exchange of the proton attached to carbon 2 of arabinosewith the solvent in the absence of metal ion. Manganese(II)is the only metal ion which renders the enzyme active for theisomerization reaction. Arabinose isomerase has high substratespecificity for L-arabinose. The difference in chemical mechanismbetween xylose isomerase and arabinose isomerase suggests thatthese enzymes are not related by convergent evolution. Thiswork also suggests that unless convergent evolution has beendemonstrated, the mechanism of one enzyme may not give any insightinto the mechanism of a second enzyme catalyzing the same reaction     

In vivo copper- and cadmium-binding ability of mammalian metallothionein domain

The ß domain of mouse metallothionein 1 (ßMT) wassynthesized in Escherichia coli cells grown in the presenceof copper or cadmium. Homogenous preparations of Cu–ßMTand Cd–ßMT were used to characterize the correspondingin vivo-conformed metal-clusters, and to compare them with thespecies obtained in vitro by metal replacement to a canonicalZn₃–ßMT structure. The copper-containing ßMTclusters formed inside the cells were very stable. In contrast,the nascent ß peptide, although it showed cadmium bindingability, produced a highly unstable species, whose stoichiometrydepended upon culture conditions. The absence of ßMT proteinin E.coli protease-proficient hosts grown in cadmium-supplementedmedium pointed to drastic proteolysis of a poorly folded ßpeptide, somehow enhanced by the presence of cadmium. Possiblefunctional and evolutionary implications of the bioactivityof mammalian ßMT in the presence of monovalent and divalentmetal ions are discussed.     

Synthesis, cloning and expression of the single-chain Fv gene of the HPr-specific monoclonal antibody, Jel42. Determination of binding constants with wild-type and mutant HPrs

The monoclonal antibody Jel42 is specific for the Escherichiacoli histidine-containing protein, HPr, which is an 85 aminoacid phosphocarrier protein of the phosphoenolpyruvate:sugarphosphotransferase system. The binding domain (Fv) has beenproduced as a single chain Fv (scFv). The scFv gene was synthesizedin vitro and coded for pelB leader peptide–heavy chain–linker–lightchain–(His)₅ tail. The linker is three repeats from theC-terminal repetitive sequence of eukaryotic RNA polymeraseII. This linker acts as a tag; it is the antigen for the monoclonalantibody Jel352. The codon usage was maximized for E.coli expression,and many unique restriction endonuclease sites were incorporated.The scFv gene incorporated into pT7-7 was highly expressed,yielding 10–30% of the cell protein as the scFv, whichwas found in inclusion bodies with the leader peptide cleaved.Jel42 scFv was purified by denaturation/renaturation yieldingpreparations with K_d values from 20 to 175 nM. However, basedupon an assessment of the amount of active refolded scFv, thebinding dissociation constant was estimated to be 2.7 ±2.0 nM compared with 2.8 ± 1.6 and 3.7 ± 0.3 nMpreviously determined for the Jel42 antibody and Fab fragmentrespectively. The effect of mutation of the antigen HPr on thebinding constant of the scFv was very similar to the propertiesdetermined for the antibody and the Fab fragment. It was concludedthat the small percentage (~6%) of refolded scFv is a true mimicof the Jel42 binding domain and that the incorrectly foldedscFv cannot be detected in the binding assay.     

Conformational modeling of substrate binding to endocellulase E2 from Thermomonospora fusca

Molecular mechanics calculations have been used to place a cellotetraosesubstrate into the active site of the crystallographlcally determinedstructure of endocellulase E2 from Thermomonospora fusca. Inthe lowest energy model structure, the second residue of thesubstrate oligosaccharide is tilted away from the planar ribbongeometry of cellulose as it is in the X–ray structureof the E2_cd–cellobiose cocrystal. This tilt is the resultof the topology of the binding site, and results in severalstrong carbohydrate–protein hydrogen bonds. The tiltingproduces a twisting of the glycosidic linkage of the cleavagesite between residues two and three. In the predicted enzyme–substratecomplex both of the Asp residues believed to function in generalacid and base roles in the previously proposed model for themechanism are distant from the bond being cleaved. Moleculardynamics simulations of the complex were conducted, and whilethe putative catalytic Asp residues remained distant from thecleavage site, the proton of Tyr73 briefly came within van derWaals contact of the linkage oxygen.     

Interchain cysteine bridges control entry of progesterone to the central cavity of the uteroglobin dimer

The progesterone–binding protein uteroglobin has beenexpressed in Escherichia coli in an unfused, soluble form. likemature uteroglobin from rabbit endometrium (UG), the E.coliproduceduteroglobin (UG1) dimerizes in vitro, forms an antiparalleldimer with Cys3–Cys69' and Cys69–Cys3' disulfidebonds and binds progesterone under reducing conditions. In orderto analyze the dimerization and the reduction dependence ofprogesterone binding in more detail, we separately replacedcysteine 3 and cysteine 69 by serines. Under reducing conditions,both uteroglobin variants (UGl–3Ser and UGl–69Ser)bind progesterone with the same affinity as the wild–typesuggesting that both cysteine residues are not directly involvedin progesterone binding. In contrast to the wild–typeprotein, both cysteine variants also bind progesterone withhigh affinity in the absence of reducing agents. In addition,UGl-3Ser and UGl-69Ser both form covalently linked homodimers.Thus, unnatural Cys69–69' and Cys3–3' disulfidebonds exist in UG1–3Ser and UG1–69Ser, respectively.These data together with computer models based on X-ray diffractiondata strongly support the idea that progesterone reaches itsbinding site located in an internal hydrophobic cavity via ahydrophobic tunnel along helices 1 and 4. Under non–reducingconditions the tunnel is closed by two disulfide bridges (Cys3–Cys69'(and Cys69–Cys3') that lie in the most flexible regionof the dimer. Reduction or replacement of a cysteine residueenables conformational changes that open the channel allowingprogesterone to enter.     

The SBASE domain library: a collection of annotated protein segments

SBASE is a database of annotated protein domain sequences representingvarious structural, functional, ligand binding and topogenicsegments of proteins. The current release of SBASE contains27 211 entries which are provided with standardized names inorder to facilitate retrieval. SBASE is cross-referenced tothe major protein and nucleic acid databanks as well as to thePROSITE catalog of protein sequence patterns [Bairoch, A. (1992)Nucleic Acids Res., 20, Suppl., 2013–2118]. SBASE canbe used to establish domain homologies through database searchusing programs such as FASTA [Lipman and Pearson (1985) Science,227, 1436–1441], FASTDB [Brutlag et al. (1990) Comp. Appl.Biosci., 6, 237–245] or BLAST3 [Altschul and Lipman (1990)Proc. Natl. Acad. Sci. USA, 87, 5509–5513], which is especiallyuseful in the case of loosely defined domain types for whichefficient consensus patterns cannot be established. The useof SBASE is illustrated on the DNA binding protein Brain-4.The database and a set of search and retrieval tools are freelyavailable on request to the authors or by anonymous ‘ftp’file transfer from <ftp.icgeb.trieste.it>.     

Development of an optimized expression system for the screening of antibody libraries displayed on the Escherichia coli surface

Polypeptide library screening technologies are critically dependentupon the characteristics of the expression system employed.A comparative analysis of the lpp–lac, tet and araBAD promoterswas performed to determine the importance of tight regulationand expression level in library screening applications. Thesurface display of single-chain antibody (scFv) in Escherichiacoli as an Lpp–OmpA' fusion was monitored using a fluorescentlytagged antigen in conjunction with flow cytometry. In contrastto the lpp–lac promoter, both tet and araBAD promoterscould be tightly repressed. Tight regulation was found to beessential for preventing rapid depletion of library clones expressingfunctional scFv and thus for maintaining the initial librarydiversity. Induction with subsaturating inducer concentrationsyielded mixed populations of uninduced and fully induced cellsfor both the tet and araBAD expression systems. In contrast,homogeneous expression levels were obtained throughout the populationusing saturating inducer concentrations and could be adjustedby varying the induction time and plasmid copy number. Underoptimal induction conditions for the araBAD system, proteinexpression did not compromise either cell viability or librarydiversity. This expression system was used to screen a libraryof random scFv mutants specific for digoxigenin for clones exhibitingimproved hapten dissociation kinetics. Thus, an expression systemhas been developed which allows library diversity to be preservedand is generally applicable to the screening of E.coli surfacedisplayed libraries.     

A thermoresistant mutant of ribonuclease T1 having three disulfide bonds

Molecular-dynamic calculations predict that, if Tyr24 and Asn84are each replaced by a Cys residue, it should be possible toform a third disulfide bond in ribonuclease T1 (RNase T1) betweenthese residues, with only minimal conformational changes atthe catalytic site. The gene encoding such a mutant variantof RNase T1 (Tyr24 – Cys24, Asn84 – Cys84) was constructedby the cassette mutagenesis method using a chemically synthesizedgene. In order to reduce the toxic effect of the mutant enzyme(RNase T1S) on an Escherichia coli host, we arranged for theprotein to be secreted into the periplasmic space by using avector that harbors a gene for an alkaline phosphatase signalpeptide under the control of the trp promoter. The nucleolyticactivity of RNase T1S toward pGpC was approximately the sameas that of RNase T1 at 37°C (pH 7.5). Moreover, at 55°C,RNase T1S retained nearly 70% of its activity while the activityof the wild-type enzyme was reduced to <10%. RNase T1S wasalso more resistant to denaturation by urea than the wild-typeenzyme. However, unlike RNase T1, RNase T1S was irreversiblyand almost totally inactivated by boiling at 100°C for 15min.     

FK506-binding protein mutational analysis: defining the active-site residue contributions to catalysis and the stability of ligand complexes

The 12 kDa FK506-binding protein FKBP12 is a cis-trans peptidyl-prolylisomerase that binds the macrolides FK506 and rapamycin. Wehave examined the role of the binding pocket residues of FKBP12in protein–ligand interactions by making conservativesubstitutions of 12 of these residues by site-directed mutagenesis.For each mutant FKBP12, we measured the affinity for FK506 andrapamycin and the catalytic efficiency in the cis–transpeptidyl-prolyl isomerase reaction. The mutation of Trp59 orPhe99 generates an FKBP12 with a significantly lower affinityfor FK506 than wild-type protein. Tyr26 and Tyr82 mutants areenzymatically active, demonstrating that hydrogen bonding bythese residues is not required for catalysis of the cis–transpeptidyl-prolyl isomerase reaction, although these mutationsalter the substrate specificity of the enzyme. We conclude thathydrophobic interactions in the active site dominate in thestabilization of FKBP12 binding to macrolide ligands and tothe twisted-amide peptidyl-prolyl substrate intermediate.     

The active site of carboxypeptidase Taq possesses the active-site motif His-Glu-X-X-His of zinc-dependent endopeptidases and aminopeptidases

Carboxypeptidase (CPase) Taq possesses the His–Glu–X–X–Hissequence, which is the consensus sequence in the active siteof zinc-dependent endopeptidases and amino-peptidases, at positions276–280. Amino acid replacement of the conserved His andGlu drastically diminished the activity of CPase Taq, and thezinc content of the enzyme was also greatly reduced when eitherof the two His residues was replaced with Arg or Tyr. The resultsindicate that this sequence actually functions as the activesite in CPase Taq, showing that CPase Taq is a novel type ofzinc-dependent CPase that possesses the His–Glu–X–X–Hisactive-site motif.     

Multimer formation as a consequence of separate homodimerization domains: the human c-Jun leucine zipper is a transplantable dimerization module

Human c-Jun and c-Fos leucine zipper domains were examined fortheir ability to serve as autonomous dimerization domains aspart of a heterologous protein construct. Schistosoma japonicumglutathione S-transferase (GST) was fused to recombinant Junleucine zipper (rJunLZ) and Fos leucine zipper (rFosLZ) domains.SDS–PAGE ‘snapshot’ analyses based on disulphidelinkage of monomers demonstrated the ability of rJunLZ to functionas a dimerization motif in a foreign protein environment. Sterichindrance prevented formation of rJunLZ–GST::rFosLZ–GSTheterodimers whereas rJunLZ–GST::rFosLZ and rJunLZ::rFosLZ–GSTformed readily. Furthermore, rJunLZ–GST generated homodimerssuggesting fusion protein heterodimers interact differentlyto homodimers. Gel filtration chromatography confirmed thatGST is a dimer in solution and that attachment of a leucinezipper domain allows further interactions to take place. Sedimentationequilibrium analyses showed that GST is a stable dimer (K_a >10⁶ M^-1) with no higher multimeric forms. rFosLZ–GST weaklyassociates beyond a dimer (K_a {small tilde}4x10⁵ M^-1) and rJunLZ–GSTassociates indefinitely (K_a {small tilde}4x10⁶ M^-1), consistentwith an isodesmic model of association. The interaction of theseleucine zippers independently of GST association demonstratestheir utility in the modification of proteins when multimerformation is desired.     

A hybrid of bovine pancreatic ribonuclease and human angiogenin: an external loop as a module controlling substrate specificity?

A comparison of the sequences of three homologous ribonucleases(RNase A, angiogenin and bovine seminal RNase) identifies threesurface loops that are highly variable between the three proteins.Two hypotheses were contrasted: (i) that this variation mightbe responsible for the different catalytic activities of thethree proteins; and (ii) that this variation is simply an exampleof surface loops undergoing rapid neutral divergence in sequence.Three hybrids of angiogenin and bovine pancreatic ribonuclease(RNase) A were prepared where regions in these loops taken fromangiogenin were inserted into RNase A. Two of the three hybridshad unremarkable catalytic properties. However, the RNase Amutant containing residues 63–74 of angiogenin had greatlydiminished catalytic activity against uridylyl-(3' – 5')-adenosine(UpA), and slightly increased catalytic activity as an inhibitorof translation in vitro. Both catalytic behaviors are characteristicof angiogenin. This is one of the first examples of an engineeredexternal loop in a protein. Further, these results are complementaryto those recently obtained from the complementary experiment,where residues 59–70 of RNase were inserted into angiogenin[Harper and Vallee (1989) Biochemistry, 28, 1875–1884].Thus, the external loop in residues 63–74 of RNase A appearsto behave, at least in part, as an interchangeable ‘module’that influences substrate specificity in an enzyme in a waythat is isolated from the influences of other regions in theprotein.     

The cystine knot of a squash-type protease inhibitor as a structural scaffold for Escherichia coli cell surface display of conformationally constrained peptides

The Ecballium elaterium trypsin inhibitor II (EETI-II), a memberof the squash family of protease inhibitors, is composed of28 amino acid residues and is a potent inhibitor of trypsin.Its compact structure is defined by a triple-stranded antiparallelß-sheet, which is held together by three intramoleculardisulfide bonds forming a cystine knot. In order to explorethe potential of the EETI-II peptide to serve as a structuralscaffold for the presentation of randomized oligopeptides, weconstructed two EETI-II derivatives, where the six-residue inhibitorloop was replaced by a 13-residue epitope of Sendai virus L-proteinand by a 17-residue epitope from human bone Gla-protein. EETI-IIand derived variants were produced via fusion to maltose bindingprotein MalE. By secretion of the fusion into the periplasmicspace, fully oxidized and correctly folded EETI-II was obtainedin high yield. EETI-II and derived variants could be presentedon the Escherichia coli outer membrane by fusion to truncatedLpp'–OmpA', which comprises the first nine residues ofmature lipoprotein plus the membrane spanning ß-strandfrom residues 46–66 of OmpA protein. Gene expression wasunder control of the strong and tightly regulated tetA promoter/operator.Cell viability was found to be drastically reduced by high levelexpression of Lpp'–OmpA'–EETI-II fusion protein.To restore cell viability, net accumulation of fusion proteinin the outer membrane was reduced to a tolerable level by introductionof an amber codon at position 9 of the lpp' sequence and utilizingan amber suppressor strain as expression host. Cells expressingEETI-II variants containing an epitope were shown to be surfacelabeled with the respective monoclonal antibody by indirectimmunofluorescence corroborating the cell surface exposure ofthe epitope sequences embedded in the EETI-II cystine knot scaffold.Cells displaying a particular epitope sequence could be enriched10⁷-fold by combining magnetic cell sorting with fluorescence-activatedcell sorting. These results demonstrate that E.coli cell surfacedisplay of conformationally constrained peptides tethered tothe EETI-II cystine knot scaffold has the potential to becomean effective technique for the rapid isolation of small peptidemolecules from combinatorial libraries that bind with high affinityto acceptor molecules.     

A proposal for the catalytic mechanism in phospholipase C based on interaction energy and distance geometry calculations

The non-specific phospholipase C from Bacillus cereus preferentiallyhydrolyses phosphatidylcholine but is also active against phosphatidylserine,phosphatidylethanolaniine and at a much lower level, sphingomyelin.A minimal substrate model containing all required structuraland configurational elements of a high affinity substrate wasdocked into the active site. The enzyme–substrate attachmentpoints were from molecular interaction energy calculations usingthe program GRID and from a previous phosphate inhibitor complexstructure. Available conformational space for the substratewas sampled by distance geometry calculations using the programDGEOM. This investigation clearly identifies the attacking nucleophile,a catalytically favourable orientation of the phosphate groupin its tetra-, as well as its penta-, coordinated state anda crucial stabilizing environment for the alkoxide intermediate.Based on this information a complete catalytic cycle is proposed.     

Structure and functional complementation of engineered fragments from yeast phosphoglycerate kinase

Previous studies have shown that, although the isolated structuraldomains of yeast phosphoglycerate kinase recover a quasi-nativestructure in vitro as well as in vivo, they do not reassociatenor generate a functional enzyme. The aim of this work was firstto study the folding of complementary fragments different fromstructural domains and second to determine the requirementsfor their reassociation and functional complementation. Themethod used for producing rigorously defined fragments consistsof the introduction of a unique cysteinyl residue in the proteinfollowed by a specific cleavage by 5'5'-dithiobis(2-nitrobenzoate)/potassiumcyanide at this residue. Two pairs of complementary fragmentswere thus obtained, 1–96/97–415 and 1–248/249–415.The structure and stabilities of the different fragments werestudied. The short fragments, i.e. 1–96 and 249–415were found to contain some secondary structure, but to havea low stability. Each large fragment has a high structural contentand a stability close to that of the corresponding domain. Incontrast to that observed with the isolated domains, a weakbut significant complementation was observed for the two pairsof fragments; the pair of fragments 1–248/249–415recovered 8% of the activity of the native enzyme upon complementation.An independent refolding of the complementary fragments beforereassociation decreased the yield of complementation for thepair of fragments 1–96/97–415, but did not affectthe complementation for the other pair (1–248/249–415).From the present data and previous work on the isolated domains,it appears that the correct folding of the isolated fragmentsis not a prerequisite for their complementation.     

Display of {beta}-lactamase on the Escherichia coli surface: outer membrane phenotypes conferred by Lpp'-OmpA'-{beta}-lactamase fusions

Bacterial cell-surface exposure of foreign peptides and solubleproteins has been achieved recently by employing a fusion proteinmethodology. An Lpp'–OmpA(46–159)–Bla fusionprotein has been shown previously to display the normally periplasmicenzyme ß-lactamase (Bla) on the cell surface of theGram-negative bacterium Escherichia coli. Here, we have investigatedthe role of the OmpA domain of the tripartite fusion proteinin the surface display of the passenger domain (Bla) and havecharacterized the effects of the fusion proteins on the integrityand permeability of the outer membrane. We show that in additionto OmpA(46–159), a second OmpA segment, consisting ofamino acids 46–66, can also mediate the display of Blaon the cell surface. Other OmpA domains of various lengths (aminoacids 46–84, 46–109, 46–128, 46–141and 46–145) either anchored the Bla domain on the periplasmicface of the outer membrane or caused a major disruption of theouter membrane, allowing the penetration of antibodies intothe cell. Detergent and antibiotic sensitivity and periplasmicleakage assays showed that changes in the permeability of theouter membrane are an unavoidable consequence of displayinga large periplasmic protein on the surface of E.coli. This isthe first systematic report on the effects that cell surfaceengineering may have on the integrity and permeability propertiesof bacterial outer membranes.     

Engineering of the substrate-binding region of the sublilisin-like, cell-envelop proteinase of Lactococcus lactis

The substrate-binding region of the cell-envelope proteinaseof Lactococcus lactis strain SK11 was modelled, based on sequencebomology of the catalytic domain with the serine proteinasessubtilisin and thermitase. Substitutions, deletions and insertionswere introduced, by site-directed and cassette mutagenesfe ofthe prtP gene encoding this enzyme, based on sequence comparisonboth with subtilisin and with the homologous L.lactis strainWg2 proteinase, which has different proteolytic properties.The engineered enzymes were investigated for thermal stability,proteolytic activity and cleavage specificity towards smallchromogenk peptide substrates and the peptide _g1-casein(l–23).Mutations in the subtilisin-like substrate-binding region showedthat Ser433 is the active site residue, and that residues 138and 166 at either side of the binding cleft play an importantrole in substrate specificity, particularly when these residuesand the substrate are oppositely charged. The K748T mutationin a different domain also affected specificity and stability,suggesting that this residue is in close proximity to the subtilisin-likedomain and may form part of the substratebinding site. Severalmutant SK11 proteinases have novel properties not previouslyencountered in natural variants. Replacements of residues 137–139AKTalong one side of the binding cleft produced the 137–139GPPmutant proteinase with reduced activity and narrowed specificity,and the 137–139GLA mutant with increased activity andbroader specificity. Furthermore, the 137–139GDT mutanthad a specificity towards _g1,-casein(l–23) closely resemblingthat of L.lactis Wg2 proteinase. Mutants with an additionalnegative charge in the binding region were more stable towardsautoproteolysis.